Analysis of metapopulation Epidemic process on arbitrary networks

Taro Takaguchi; Renaud Lambiotte

doi:10.1016/j.ifacol.2015.11.026

Analysis of metapopulation Epidemic process on arbitrary networks

Namur Institute for Complex Systems

Résultats de recherche: Contribution dans un livre/un catalogue/un rapport/dans les actes d'une conférence › Article dans les actes d'une conférence/un colloque

Résumé

Epidemic process on networks is considered. The system is discribed as a metapopulation network in which a node represents subpopulation (e.g., city or school) and is connected to other nodes via undirected links. Particles represent the subject of infection (e.g., individuals) and interact with each other within nodes while migrating from nodes to nodes in the manner of random diffusion. The nonlinear dependence of contact rate within a node on its population size is introduced, according to the recent finding based on emprical phone-call data. The impacts of the nonlinear dependence are investigated for three aspects of epidemic process: epidemic threshold, infection size at stationary state, and transient dynamics.

langue originale	Anglais
titre	IFAC Proceedings Volumes (IFAC-PapersOnline)
Editeur	IFAC Secretariat
Pages	141-145
Nombre de pages	5
Volume	48
Edition	18
Les DOIs	https://doi.org/10.1016/j.ifacol.2015.11.026
Etat de la publication	Publié - 1 nov. 2015
Evénement	4th IFAC Conference on Analysis and Control of Chaotic Systems, CHAOS 2015 - Tokyo, Japon Durée: 26 août 2015 → 28 août 2015

Une conférence

Une conférence	4th IFAC Conference on Analysis and Control of Chaotic Systems, CHAOS 2015
Pays/Territoire	Japon
La ville	Tokyo
période	26/08/15 → 28/08/15

Accès au document

10.1016/j.ifacol.2015.11.026

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title = "Analysis of metapopulation Epidemic process on arbitrary networks",

abstract = "Epidemic process on networks is considered. The system is discribed as a metapopulation network in which a node represents subpopulation (e.g., city or school) and is connected to other nodes via undirected links. Particles represent the subject of infection (e.g., individuals) and interact with each other within nodes while migrating from nodes to nodes in the manner of random diffusion. The nonlinear dependence of contact rate within a node on its population size is introduced, according to the recent finding based on emprical phone-call data. The impacts of the nonlinear dependence are investigated for three aspects of epidemic process: epidemic threshold, infection size at stationary state, and transient dynamics.",

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AU - Lambiotte, Renaud

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AB - Epidemic process on networks is considered. The system is discribed as a metapopulation network in which a node represents subpopulation (e.g., city or school) and is connected to other nodes via undirected links. Particles represent the subject of infection (e.g., individuals) and interact with each other within nodes while migrating from nodes to nodes in the manner of random diffusion. The nonlinear dependence of contact rate within a node on its population size is introduced, according to the recent finding based on emprical phone-call data. The impacts of the nonlinear dependence are investigated for three aspects of epidemic process: epidemic threshold, infection size at stationary state, and transient dynamics.

KW - Complex systems

KW - Differential equations

KW - Eigenmode analysis

KW - Monte carlo simulation

KW - Networks

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EP - 145

BT - IFAC Proceedings Volumes (IFAC-PapersOnline)

PB - IFAC Secretariat

T2 - 4th IFAC Conference on Analysis and Control of Chaotic Systems, CHAOS 2015

Y2 - 26 August 2015 through 28 August 2015

ER -

Analysis of metapopulation Epidemic process on arbitrary networks

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